RU2761758C1 - Inventions related to a capacitive media interface level sensor - Google Patents

Abstract

FIELD: physical chemistry.

SUBSTANCE: invention is intended for measuring the levels of the interface of media in various industries. The fluid flow monitoring system contains several capacitive level sensors of the media interface and a server device for providing user information about the fluid flow in the container in which the corresponding sensor is installed. Each capacitive level sensor of the interface of media contains a base, a sensing element, and the base contains the first part containing a niche with a lid for hermetically placing an electronic computing unit and a hole for the output cable of the electronic computing unit, the second part, which has holes for embedded bushings, has holes for fasteners on the side surface, has ventilation holes on the side surface. Moreover, the sensing element is a housing for electrodes, which is a metal profile formed by connecting several tubes to each other, containing a stiffening element connecting the adjacent profile tubes mentioned.

EFFECT: increase in reliability, manufacturability of the product and measurement accuracy.

14 cl, 32 dwg

Description

[0001] TECHNICAL FIELD

[0002] The proposed technical solution relates to measuring technology, intended for measuring the levels of interfaces between media and can be used in various industries.

[0003] BACKGROUND

[0004] Known capacitive sensor for the level of liquids, described in patent US3901079, published on 08/26/1975 on 12 sheets (D1). The capacitive liquid level sensor known from D1 comprises a housing for accommodating the electronic computing equipment of the sensor, connected to the housings for accommodating the electrode probes of the sensor.

[0005] The disadvantage of the sensor known from D1 is its low operational reliability and high measurement error, caused mainly by insufficiently effective and reliable design of the housing for accommodating the electrode probes of the sensor.

[0006] DISCLOSURE OF THE INVENTION

[0007] The technical problem solved by the claimed invention is to provide a capacitive interface level sensor with high operational reliability and high measurement accuracy, capable of measuring interface levels of liquid media with different dielectric constants without the need for additional calibration of the capacitive sensor.

[0008] The technical result achieved by using the claimed invention is to eliminate the shortcomings of the prototype, increase the reliability and manufacturability of the design, and, as a result, increase the accuracy of measurements of the interface level, as well as provide the ability to measure the levels of interfaces of liquid media with different dielectric permittivities without the need for additional calibration of the capacitive sensor.

[0009] The technical result is achieved due to the fact that there is provided a system for monitoring the flow rate of a liquid, containing several capacitive sensors for the interface level, configured to communicate with the server device to provide user information about the flow rate of liquid in a container in which the corresponding sensor is installed; and a server device for providing user information about the flow rate of the liquid in the container in which the corresponding sensor is installed; moreover, each capacitive sensor of the interface level contains: a base; sensitive element of the sensor; moreover, the base contains: the first part containing a niche with a cover for sealed placement of the electronic computing unit and an opening for the output cable of the electronic computing unit; the second part, which: predominantly in the center in the area of the first part has holes for insert sleeves; has holes for fasteners on the side surface; has ventilation holes on the side surface; moreover, the sensitive element of the sensor is a housing for electrodes, which is a metal profile formed by connecting several tubes to each other, containing a stiffener connecting the adjacent said profile tubes; wherein each profile tube contains a ventilation hole located coaxially with said corresponding ventilation hole on the side surface of said collar portion; and contains on its side adjacent to the measured medium, a slot aligned axially with said corresponding ventilation hole on the side surface of said collar part; in this case, the housing for the electrodes contains electrodes rigidly fixed in each of the profile tubes, which are metal tubes with the same linear capacity, but differing in length, and the main electrode is made in length, mainly equal to the length of the housing for the electrodes, and each compensation electrode is made according to a length less than the length of the main electrode; moreover, the sensitive element of the sensor is connected to the base through the holes for the fasteners; moreover, the main electrode and each compensation electrode are connected to the electronic computing unit by means of metal rods connected to the insert sleeves, which are connected to the holes for the insert sleeves.

[0010] BRIEF DESCRIPTION OF DRAWINGS

[0011] Exemplary embodiments of the present invention are described in detail below with reference to the accompanying drawings, which are incorporated herein by reference and in which:

[0012] FIG. 1 shows an exemplary general view of a preferred embodiment of the claimed capacitive sensor for measuring the level of the interface between media.

[0013] FIG. 2 shows an approximate general view of the component composition for the preferred embodiment of the claimed capacitive sensor for measuring the level of the interface between the media.

[0014] FIG. 3 shows an exemplary cross-sectional view of the housing for electrodes for a preferred embodiment of the claimed capacitive sensor for measuring the interface level.

[0015] FIG. 4 shows an exemplary general view of the first alternative embodiment of a capacitive sensor for measuring the interface level.

[0016] FIG. 5 is an exemplary cross-sectional view of an electrode housing for an exemplary first alternative embodiment of a capacitive interface level sensor.

[0017] FIG. 6 shows an exemplary general view of a second alternative embodiment of a capacitive sensor for measuring the interface level.

[0018] FIG. 7 is an exemplary cross-sectional view of an electrode housing for an exemplary second alternative embodiment of a capacitive interface level sensor.

[0019] FIG. 8-11 depict an exemplary cross-sectional view of an electrode housing for exemplary other alternative embodiments of a capacitive interface level sensor.

[0020] FIG. 12-21 schematically illustrate exemplary other embodiments of a cross-section of a housing for electrodes for exemplary other alternative embodiments of a capacitive sensor for measuring the interface level.

[0021] FIG. 22 depicts an exemplary method of using a coupling for a capacitive sensor electrode housing.

[0022] FIG. 23-24 shows an approximate circuit diagram of the claimed capacitive sensor for measuring the interface level.

[0023] FIG. 25 is an exemplary general diagram of a fluid flow monitoring system.

[0024] FIG. 26 shows an approximate most typical placement of the claimed capacitive sensor in a container with a measured medium.

[0025] FIG. 27 shows an approximate most typical placement of several declared capacitive sensors in a container with a measured medium.

[0026] FIG. 28 shows the most typical placement of several declared capacitive sensors in a container with a measured medium having an uneven geometry.

[0027] FIG. 29 shows an approximate most typical placement of the claimed capacitive sensor in a vertical vessel with a measured medium.

[0028] FIG. 30 shows an exemplary diagram of the method for assembling the components of the inventive capacitive sensor for measuring the interface level.

[0029] FIG. 31 shows an exemplary diagram of the method for preliminary calibration of the claimed capacitive sensor for measuring the interface level.

[0030] FIG. 32 shows an exemplary diagram of the implementation of the method for measuring the interface level when using the claimed capacitive sensor for measuring the interface level.

[0031] CARRYING OUT THE INVENTION

[0032] The following are embodiments of the present invention, revealing examples of its implementation in private versions. However, the description itself is not intended to limit the scope of the rights conferred by this patent. Rather, it should be understood that the claimed invention may also be practiced in other ways in a manner that would include different elements and conditions, or combinations of elements and conditions similar to those described herein, in combination with other existing and future technologies.

[0033] FIG. 1, by way of example and not limitation, an exemplary preferred embodiment of the claimed capacitive interface level sensor 100 (sensor 100) is presented. As seen in FIG. 1, the claimed sensor 100 generally consists of a base 1010 and a housing 1020 for electrodes of the sensor 100, which, when the electrodes are placed therein, is the sensing element of the sensor 100.

[0034] FIG. 2, by way of example and not limitation, an exemplary general view of the composition of the composition for one of the preferred embodiments of the claimed sensor 100 is presented. As can be seen from FIG. 2, the composition of the sensor 100 can be determined by the presence of the following components: base 1010; housings 1020 for electrodes 1031, 1032, optionally with at least one stiffener 1021 and optionally with at least one coupler 1028 (FIG. 22); electrodes 1031, 1032, optionally with spacer rings 1033; insert sleeves 1040, optionally with o-rings 1041; metal connecting rods 1050; electronic computing unit 1060.

[0035] The base 1010 is intended to accommodate an electronic computing unit 1060, which will be described in detail below, and connect the electrodes 1031, 1032 of the sensor to the input of the electronic computing unit 1060. The base 1010 is most typically made in the form of a collar flange, the first part of which, for example without limitation, the flat portion 1011 can be made in any shape, for example, not limited to the shape of a circle, ellipse or polygon, and the second part of which, for example, but not limited to, the collar portion 1012, preferably, but not limited to, is made in the shape of a fastening sleeve, the shape of the hole of which can also be any, for example, but not limited to, in the shape of a circle, an ellipse or in the shape of a polygon. As will become apparent to a person skilled in the art, the shape of the fastening sleeve and, accordingly, the openings of the collar portion 1012 are mainly determined by the cross-sectional shape of the housing 1020 for the electrodes 1031, 1032 of the sensor and are chosen so as to ensure reliable fixation of the housing 1020 for the electrodes 1031. 1032 in the collar 1012. In addition, the difference from the conventional collar flange is that the base 1010 does not contain a through hole in the center of the collar 1012, but contains several through holes containing threads (not shown), the number of which corresponds to the number of electrodes 1031, 1032 sensors. Said threaded holes are formed so as to position the electrode housing 1020 1031, 1032 such that the mounting holes of the tubes 1022, 1023 of the electrode housing 1020 1031, 1032 are aligned with the respective said threaded holes. To attach the housing 1020 for the electrodes 1031, 1032 to the collar portion 1012, holes 10121 are made on the sides for fastening elements, which can be, but are not limited to, blind rivets. In addition, in the collar part 1012, preferably, although not necessarily, also on opposite sides, preferably asymmetrically formed in the vicinity of the flat part 1011, ventilation holes 10122, intended for the flow of gas (mixture of gases) into the housing 1020 for the electrodes 1031, 1032 and ensuring an equal level the measured medium in communicating vessels, one of which is the aforementioned housing 1020, and the other is a container for the measured medium. In addition, from the side on the reverse side, on which the collar part 1012 is located, the flat part 1011 contains a niche 1013 for accommodating an electronic computing unit 1060. As will become apparent to a person skilled in the art, the shape of the niche 1013 can also be any, for example, not limited to round, elliptical or polygonal, and is mainly determined by the shape of the printed circuit board of the electronic computing unit 1060. However, the shape of the niche 1013 should be chosen such that it is possible to reliably seal the niche with a compound after installing the electronic computing unit 1060, followed by installation of the cover 1014 for the niche 1013. In addition, the shape of the niche 1013 should be chosen such as to allow the output cable 1063 containing the connector of the electronic computing unit 1060 through the opening 1015 in the niche 1013. In addition, in the future, the niche 1013 with the computing unit installed therein block 1060, covered with a lid 1014 for niche 1013 may be covered with a lid 1070, preferably made of copolymer materials such as polyacetal, polyamide, polycarbonate, and the like, in a shape that allows sufficient coverage of niche 1013.

[0036] Preferably, the base 1010 is made of metal. However, while providing sufficient structural rigidity, the base 1010 can also be made from copolymer or from combinations thereof, including metal. Preferably, the base 1010 is manufactured by injection molding or milling.

[0037] The housing 1020 for electrodes 1031, 1032 (housing 1020) is a metal profile formed by joining at least two tubes of the same or different (for example, when used without a coupling and compensation electrode 1032 is shorter than the main electrode 1031) length among themselves, at least partially along the length of the profile. Optionally, the body 1020 may include one or more stiffeners 1021, preferably, although not necessarily, along the entire length of the body 1020 and in contact with each of the tubes, or at least two adjacent tubes. These tubes have mounting holes 1022, 1023 and inlets 1024, 1025 (not shown in FIG. 2). As seen in FIG. 2, it is preferable that at the junction of said housing 1020 with said collar portion 1012 of said base 1010, corresponding ventilation holes 10201 are provided, arranged coaxially with corresponding ventilation holes 10122 in the collar portion 1012, thereby allowing air to enter the interior of said housing 1020. , each tube may have at least one slot 1026 (for example, Fig. 3), made at least partially along the length of the tube on at least one of its side adjacent to the measured medium. Preferably, slot 1026 is formed along the entire length of each tube. It is preferable that the width of the slot does not exceed 15 mm. Although it is also preferable that the slots 1026 on each of the tubes are made symmetrically or at equal angles with respect to each other, nevertheless, the slots 1026 can be made in other ways, for example, without limitation, at unequal angles with respect to each other. ... At the same time, the main purpose of the slots 1026 is to provide access of the measured medium to the housing 1020 from the side of each tube containing the electrode 1031 or 1032. Proceeding from this, the implementation of the slots 1026 should be carried out in such a way that at the junction of the said housing 1020 with the said collar part 1012 of said base 1010, said slots 1026 were placed coaxially with ventilation holes 10122, thereby allowing gas (mixture of gases) to flow into said housing 1020. In the base of housing 1020, holes 1027 are made, coaxial to holes 10121 in the collar portion 1012 of base 1010, through which the body 1020 and the base 1010 are fastened together. Thus, due to the execution of the slot 1026, in contrast to the prototype and similar devices, inertia-free measurements can be additionally ensured, and clogging of the tube due to paraffinization of the measured medium is excluded, which, as a result, will lead to even more increasing the reliability and manufacturability of the design and, as a consequence, increasing the accuracy of measuring the interface level.

[0038] FIG. 3-21, by way of example and not limitation, exemplary possible cross-sections of the tubes forming the body 1020 are shown. It is preferred, although not necessary, that the shape of the electrodes 1031, 1032 also changes depending on the cross-sectional shape, thus to match the cross-sectional shape of the tubes that make up the housing 1020 - this can provide a larger capacitor area for more accurate measurements. In this case, although shown in FIG. 3-21 exemplary possible embodiments of the cross-section of the tubes forming the said body 1020 contain slots 1026, preferably they contain corresponding ventilation openings 10201, and the access of the measured medium inside the said tubes is carried out by means of the inlet openings 1024, 1025. Thus, the mentioned ventilation openings holes 10201 and slots 1026 are equivalent in their primary function. Given that such a cross-sectional shape can be any, in particular, not limited to, in the form of a circle, ellipse or polygon or combinations thereof, and there can be more than two electrodes 1031, 1032, it should be obvious to a person skilled in the art, that the main principle in the design of the housing 1020 is that the housing 1020 as a whole should have sufficient bending rigidity, ensure reliable rigid fixation of the electrodes 1031, 1032 inside the tubes, and ensure the possibility of making a slot 1026. These requirements are most relevant in the case of a large length of the housing 1020, since with a large length of the housing 1020 during operation, bending along its length can occur, which will lead to a violation of the geometry of the sensor's sensitive element formed by the outer boundary of the housing 1020 and the electrodes 1031, 1032 placed in its tubes. Such a change in geometry leads to a significant decrease in the measurement accuracy and reduces the operational reliability of the sensor as a whole. To provide sufficient flexural rigidity, the body 1020 can optionally be supplemented with at least one stiffener 1021. Such a stiffener 1021, as previously mentioned, is formed along the entire length of the body 1020 at the point of contact of at least two tubes. Such a stiffener provides additional bending stiffness and prevents unwanted changes in the geometry of the sensor element. In some cases, for example, as shown in FIG. 5, 10, 11, 12, 21, the cross-section of the housing 1020 is made such that it already provides sufficient rigidity and the reinforcement 1021 is not required. The cross-sectional shape of such a stiffener 1021 is also chosen such that sufficient flexural rigidity is provided for the body 1020 as a whole. As an example, the cross-sectional shapes of such a stiffener 1021 other than a circle are shown in FIG. 8, 14, 16, 17, 19, 20.

[0039] The sensing element of the sensor 100 is formed by placing electrodes 1031 and 1032 in the housing 1020, which thus form several capacitive measuring channels, one of which is the main one, and the rest are compensation. Electrodes 1031 and 1032 have identical parameters, in particular, they have identical linear capacitance, but, nevertheless, differ in length. The electrode 1031 is the main one and is made mainly for the entire length of the housing 1020, and the electrode 1032 or electrodes 1032 are compensating and made for a length shorter, in particular, but not limited to, much less than the length of the electrode 1031. The electrodes 1031, 1032 are preferably rigidly fixed inside the corresponding tubes of the body 1020. In some cases, the fixation of the electrodes 1031, 1032 can be carried out by threading them with spacer rings 1033 having protrusions along the edges, allowing at least partially to create an abutment against the walls of the tube, and at least partially to ensure fixation rings due to the protrusion in the slot 1026. Said spacer rings 1033 are preferably placed in such a way as to ensure the best alignment of the electrode 1031, 1032 in the corresponding tube of the housing 1020. It will be obvious to the person skilled in the art that depending on the length of the electrode 1031, 1032 to ensure its rigid fixation in the tube e housing 1020 can be sufficient as one spacer ring 1033 (if the length of the electrode is small, as in the case of electrodes 1032), and several spacer rings 1033 (if the length of the electrode is long, as in the case of electrode 1031). In this case, it should be assumed that the number of spacer rings 1031 should be such that the effect on the measurement accuracy is minimal, but that a sufficiently rigid fixation of the electrodes 1031, 1032 in the tubes of the housing 1020 is ensured to maintain the stability of the geometry of the sensitive element of the sensor 100.

[0040] Said electrodes 1031, 1032 are tubes made of metal. In case the sensor 100 is used to measure the interface level of the interface of media, one of which is a dielectric liquid, for example, but not limited to, kerosene, gasoline, other types of fuel, electrodes 1031, 1032 do not require additional improvements. However, if the sensor 100 is used to measure the interface level of media, one of which is a liquid with electrical conductivity, for example, but not limited to water, electrodes 1031, 1032 are additionally provided along their entire length with an insulating shell, such as, for example, but not limited to, a PTFE sheath.

[0041] The connection of the measuring channels to the input of the electronic computing unit 1060 is carried out by means of threaded metal rods 1050, onto which, preferably made of dielectric material, insert sleeves 1040 are screwed in the manner shown in FIG. 2. Optionally, the bushings 1040 may include o-rings 1041. The bushings 1040 are threaded at their upper portion to be threaded to said threaded holes in the flat portion 1011 of the base 1010. However, it should be assumed that the connection of the electrodes 1031, 1032 to the electronic computing unit 1060 must be sealed, and it should be obvious to a person skilled in the art that only a separate embodiment of such a connection has been demonstrated above. From the side of the niche 1013 and, accordingly, the electronic computing unit 1060, the electrical connection of the metal rods 1050, which are thus extensions of the electrodes 1031, 1032, with the input of the electronic computing unit 1060 is carried out by installing and fixing the electrodes 1031, 1032 on the insert sleeves 1040 by means of, for example, but not limited to nuts, lock washers, and liquid thread lock.

[0042] The length of the body 1020 can be substantially increased due to the coupling 1028 (Fig. 22), which is a cylinder, which preferably in section, or at least in the section of its holes in its bases, repeats the general section of the body 1020 and on its lateral surface contains coaxial slots 10281, made mainly along the entire height of the sleeve and on a larger area of the lateral surface. Thus, it should be assumed that such a coupling 1028 provides a minimal effect on the overall geometry of the sensitive element of the sensor 100, especially considering that its length is much less than the length of the housing 1020. In this case, those parts of the side surface of the coupling 1028 that do not contain the slots 10281 are designed so that, when connected to the body 1020, they do not overlap the slots 1026 of the body 1020, if the body 1020 has them. Coupling 1028 is designed to rigidly and reliably connect two bodies 1020 that are identical in geometry and optionally in length. The electrode 1031 (optionally also the electrode 1032) is provided by connecting the two parts of the electrode 1031 together by means of a metal rod 1029, for example, but not limited to, a metal rod similar to the metal rod 1050 using similar fasteners. The connection of the sleeve 1028 to the corresponding parts of the housing 1020 is carried out, for example, but not limited to, by means of the clamping screws 10282.

[0043] It is preferred, although not necessary, that the electrodes 1031, 1032, the body 1020, the coupler 1028, and the connecting rods 1050 are made of the same material.

[0044] An electronic computing unit 1060 is used to generate a magnetic field in the sensing element of the sensor 100 and convert the received analog signal into a digital signal that can be transmitted to a visualization unit or to a fluid flow monitoring system. As shown in FIG. 23 and FIG. 24, electronic computing unit 1060 most typically contains an analog part 1061 and a digital part 1062. The analog part 1061 most typically contains: an RC oscillator formed by the resistances and capacitances of the measured channels 1031, 1032, optionally a capacitive galvanic isolator formed by capacitors C1, C3, intended for protection against a short circuit at the input of the computing unit 1060 for cases when the measured medium is flammable, an analog switch 10611 designed to switch between measuring channels 1031, 1032, and depending on the number of measuring channels, a greater number of analog switch inputs 10611 can be provided and, accordingly , additional capacitors to provide additional capacitive galvanic isolators, comparator 10612, designed to detect frequency pulses coming from the RC generator, having an amplitude above a certain predetermined threshold voltage for their subsequent counter, a reference voltage 10613, designed to provide a stable reference voltage, optionally, a square-wave shaper 10614, designed to align non-rectangular pulses detected by the comparator, and a galvanic isolator 10615 (capacitive or inductive type), designed to protect against short circuits at the analog output parts 1061 of the computing unit 1060 for cases when the measured medium is combustible. Digital portion 1062 most typically comprises a microcontroller 10621 coupled to a non-volatile memory 10622, a crystal oscillator 10623, and an interface 10624, such as, for example, but not limited to an RS-485 interface. At the same time, it should be obvious to a person skilled in the art that the non-volatile memory, interface and crystal oscillator can be made both as independent electronic components and as components that make up the microcontroller as such. In this case, as can be seen from FIG. 23 and 24, by way of example and not limitation, the galvanic isolator 10615 may be provided with filtering power capacitors designed to improve the reliability of the circuitry of the computing unit 1060. In turn, by way of example and not limitation, the non-volatile memory 10622 connection circuit may comprise resistance to ensure the selection of the operating mode; and the filtering capacity of the supply, designed to increase the reliability of operation. In turn, by way of example, and not limitation, crystal oscillator 10623 may include an impedance equalizing resistor strap to provide frequency stability for the crystal oscillator of capacitors. In turn, by way of example, and not limitation, the interface 10624 at the input of the circuitry of the computing unit 1060 may include resistors for protection against electrostatic and conducted noise, equipped with suppressors (protection diodes) designed to protect against electrostatic discharges and conducted noise of large amplitude.

[0045] The digital signal generated during the measurements by the electronic computing unit 1060 is transmitted via the output cable 1063 to the visualization unit for displaying the current measurements and / or to the fluid flow monitoring system. As shown in FIG. 25 most typically, such a fluid flow monitoring system 200 may comprise one or more sensors 100 and a server device 200. In this case, the sensors 100 are connected to a transceiver 101 or a plurality of transceivers 101 providing a wired or wireless or combined connection. sensors 100 with a server device 200. Such a transceiver device is configured to transmit information coming from the output cable 1063 of the sensor 100 to a server device 200. In some cases, such a transceiver device 101 may be equipped with navigation equipment for transmitting information to the server device as well about the location of the corresponding sensor 100. In turn, the server device 200, which is most typically made in the form of a computing device containing a processor, memory and, optionally, an input / output device, is configured to receive information from the corresponding transmitting and receiving devices 101, processing and providing, including through a web interface, information about the status and / or location of each sensor 100.

[0046] FIG. 26-29 show exemplary methods of placing a sensor 100 in a container 300 with a measured medium. Such a capacity 300 can be any suitable container, such as, but not limited to, a canister, including a fuel canister, a tank, including a fuel tank, including a rocket fuel tank, a tanker, including a tanker or railroad cistern, tank, including tanker tank or underground tank and the like. The top wall of a suitable container is at least partially solid. In this continuous part of it, the sensor 100 is rigidly mounted on the base 1010 so that its sensing element (housing 1020 with electrodes 1031, 1032) is oriented vertically and is located mainly in the central part of the container 300. Depending on the dimensions of the container 300, to ensure sufficient accuracy measurement container 300 may contain several sensors 100 (Fig. 27). In addition, depending on the geometry of the container 300, the body 1020 is elongated by a similar body through the coupling 1028 (FIG. 29). In addition, in the case of using several sensors 100 in one container 300, which has a predominantly constant geometry around the perimeter (Fig. 27), it is preferable to arrange the sensors 100 in opposite corners of the container. In addition, in the case of using several sensors 100 in one container 300 having a geometry that is not constant along the perimeter, for example, having different heights in its different parts (Fig. 28), it is preferable to arrange the sensors 100 in the center of each such part, as if the only the sensor 100 was housed in a container 300 having a predominantly constant geometry.

[0047] As shown in FIG. 30, it is preferable that the assembly of the sensor 100 by the assembly method 400 proceeds as follows. In step 401, insert sleeves 1040 connected to metal rods 1050 are connected to base 1010 through said threaded holes. Then, in step 402, the electronic computing unit 1060 is installed in the niche 1013. Then, in step 403, the output cable 1063 is soldered to the computing unit 1060. Thereafter, in step 404, the cover 1014 is installed to close the niche 1013, after which sealing is performed with a compound through the hole with thread 1015. Thereafter, at step 405, the output cable 1063 is twisted into a threaded hole 1015. After sufficient solidification of the compound, a preliminary calibration is carried out in step 406, which consists in bringing the values obtained from the compensation measuring channels, which are one or more channels formed at this stage, one or more metal rods 1050, to the value obtained from the main measuring channel, which is only one channel formed at this stage by only one metal rod 1050, the correction factors are calculated and recorded in the ene Compute unit 1060 non-volatile memory. Electrodes 1031 and 1032 are then screwed onto metal rods 1050 in step 407 to provide their primary connection to computing unit 1060. Optionally, at step 4071, electrodes 1031, 1032 may be provided with insulation. After that, at step 408, the body 1020 is installed by threading it onto the electrodes 1031, 1032, and the body 1020 is rigidly fixed in the collar part 1012 of the base 1010, for example, without limitation, using rivets, and the electrodes 1031, 1032, if necessary, are rigidly fixed in the tubes housing 1020 by means of spacer rings 1033.

[0048] As shown in FIG. 31, it is preferable that said pre-calibration of the sensor 100 in step 406 is performed as follows.

[0049] In step 4061, the capacitance of the main measurement channel is measured.

[0050] At an optional step 40611, by means of the microcontroller of the computing unit 1060, in order to obtain the reduced value of the capacitance of the main measuring channel, the measured value of the capacitance of the main measuring channel is brought to the value of the capacitance at the reference temperature, using the temperature compensation coefficient, the value of which was previously stored in the non-volatile memory block 1060.

[0051] In step 4062, the capacitance of each compensation measurement channel is measured.

[0052] At an optional step 40621 by means of the microcontroller of the computing unit 1060 to obtain the reduced value of the capacitance of the compensation measurement channel, the measured value of the capacitance of each compensation measurement channel is brought to the value of the capacitance at the reference temperature, using for this the temperature compensation coefficient, the value of which was previously stored in the non-volatile memory computing unit 1060.

[0053] In step 4063, by means of the microcontroller of the computing unit 1060 to obtain the values of the primary correction factors, the differences between each value (reduced value) of the capacitance of the compensation measurement channel and the value (reduced value) of the capacitance of the main measurement channel are calculated.

[0054] In step 4064, steps 4061-4063 are iteratively repeated to obtain a set of primary correction factors for a specified time interval, which preferably does not exceed 30 minutes.

[0055] At step 4065, by means of the microcontroller of the computing unit 1060 to obtain the value of the averaged correction factor, this value is calculated based on the primary values of the correction factors from the set of primary values of the correction factors, and the obtained averaged value of the correction factor is written into the non-volatile memory of the computing unit 1060 of the sensor 100.

[0056] As shown in FIG. 32, it is preferable that the measurement of the interface level in the framework of the method 500 for measuring the interface level is carried out as follows.

[0057] In step 501, the sensor 100 is calibrated as follows.

[0058] At step 5011, the sensor 100 is installed in a container that does not contain a medium to be measured.

[0059] At step 5012, the values of the capacitances of the main and each compensation measuring channels of the sensor 100 are measured for a container not containing the measured medium, while each measurement of the capacitance value of each compensation measuring channel is carried out taking into account the averaged correction factor, the value of which is contained in the non-volatile memory of the computing unit 1060.

[0060] At an optional step 50121 to obtain the reduced values of the capacitances of the measuring channels for a container that does not contain the measured medium, the values of the capacitances of the measuring channels measured at step 5012, by means of the microcontroller of the computing unit 1060, lead to the values of the capacitances of the measuring channels at a reference temperature, using for this the temperature compensation coefficient, the value of which was previously recorded in the non-volatile memory of the computing unit 1060.

[0061] At step 5013, the container is filled with a reference medium to be measured to the maximum allowable level for that container.

[0062] At step 5014, the values of the capacitances of the main and each compensation measuring channel of the sensor 100 are measured for the container containing the reference measured medium, while each measurement of the capacitance value of each compensation measuring channel is carried out taking into account the averaged correction factor, the value of which is contained in the non-volatile memory of the computing unit 1060.

[0063] In an optional step 50141, to obtain the reduced values of the capacitances of the measuring channels for the container containing the reference medium, the values of the capacitances of the measuring channels measured in step 5014, by means of the microcontroller of the computing unit 1060, to the values of the capacitances of the measuring channels at the reference temperature, using for this the temperature compensation coefficient, the value of which was previously recorded in the non-volatile memory of the computing unit 1060.

[0064] In step 5015, based on the values obtained in steps 5012 and 5014, or based on the reduced values obtained in steps 50121 and 50141, by the microcontroller of the computing unit 1060, the calibration values of the capacitance difference are calculated using pairwise each value of the compensation channel capacitance obtained in steps 5012 and 5014, and the capacitance value of the main measurement channel obtained in steps 5012 and 5014, or using pairwise each corrected value of the compensation channel capacitance obtained in steps 50121 and 50141, and the reduced value of the capacitance of the main measurement channel obtained in steps 50121 and 50141, and the obtained calibration values of the capacitance difference are recorded in the non-volatile memory of the computing unit 1060.

[0065] In step 5016, which may precede step 5015 or be performed in parallel with step 5015, based on the values obtained in steps 5012 and 5014 or based on the reduced values obtained in steps 50121 and 50141, the microcontroller of the computing unit 1060 calculates the dynamic range of the interface level media, and the dynamic range of the interface level is the difference between the capacity value of the main measuring channel for the full capacity and the capacity value of the main measuring channel for the empty tank, and the obtained values of the dynamic range of the interface level are recorded in the non-volatile memory of the computing unit 1060.

[0066] In step 502, the interface level is measured using the sensor 100 calibrated in step 501 as follows.

[0067] At step 5021, the container is filled with the medium to be measured to a level at which the longest compensation channel of the sensor 100 is at least partially immersed in the measured medium, the measured medium being different from the reference medium; or fill the container with the reference medium to be measured to any level admissible for this container.

[0068] At step 5022, the values of the capacitances of the main and each compensation measuring channel of the sensor 100 are measured for the container containing the measured medium, and each measurement of the capacitance value of each compensation measuring channel is carried out taking into account the averaged correction factor, the value of which is contained in the non-volatile memory of the computing unit 1060 ...

[0069] At an optional step 50221 to obtain the reduced values of the capacitances of the measuring channels for the container containing the measured medium, the values of the capacitances of the measuring channels, measured at step 5022, by means of the microcontroller of the computing unit 1060 lead to the values of the capacitances of the measuring channels at the reference temperature using the coefficient temperature compensation, the value of which was previously recorded in the non-volatile memory of the computing unit 1060.

[0070] In step 5023, to obtain the values of the capacitance difference by the microcontroller of the computing unit 1060, the values of the capacitance difference are calculated using pairwise each value of the capacitance of the compensation channel obtained in step 5022 and the value of the capacitance of the main measuring channel obtained in step 5022, or using pairwise each reduced value of the capacitance of the compensation channel, obtained in step 50221, and the reduced value of the capacitance of the main measuring channel, obtained in step 50221.

[0071] In step 5024, by means of the microcontroller of the computing unit 1060, to obtain the correction factor value, the capacitance difference values obtained in step 5023 are compared with the capacitance calibration values, and the capacitance difference ratio, which is the correction factor, is calculated.

[0072] In step 5025, to obtain the value of the interface level capacitance, each capacitance value of the main measurement channel by the microcontroller of the computing unit 1060 is brought to the capacitance value of the interface level using the correction factor, the value of which was obtained in step 5024.

[0073] In step 5026, the obtained values of the interface capacitances are used by the microcontroller of the computing unit 1060 to determine the relative interface level in accordance with the dynamic range values stored in the memory of the computing unit 1060.

[0074] By obtaining the value of the averaged correction factor in step 4065, it is possible to measure the interface level of media with a dielectric constant different from the dielectric constant of the reference medium to be measured. Thus, due to the use of the averaged correction factor, it is not required to carry out additional calibration of the capacitive sensor when the dielectric constant of the measured medium changes, for example, when changing the type of fuel or its characteristics.

[0075] The present description of the implementation of the claimed invention demonstrates only particular embodiments and does not limit other embodiments of the claimed invention, since possible other alternative embodiments of the claimed invention, which do not go beyond the scope of information set forth in this application, should be obvious to a person skilled in this technical field of ordinary skill for which the claimed invention is designed.

Claims (25)

1. A system for monitoring the flow rate of a liquid, containing several capacitive sensors for the level of the interface between the media, configured to communicate with the server device to provide user information about the flow rate of liquid in the container in which the corresponding sensor is installed; and a server device for providing user information about the flow rate of the liquid in the container in which the corresponding sensor is installed; moreover Each capacitive interface level sensor contains: base; sensitive element of the sensor; and the base contains: the first part containing a niche with a cover for sealed placement of the electronic computing unit and an opening for the output cable of the electronic computing unit; the second part, which: predominantly in the center in the area of the first part has holes for insert sleeves; has holes for fasteners on the side surface; has ventilation holes on the side surface; moreover, the sensitive element of the sensor is a housing for electrodes, which is a metal profile formed by connecting several tubes to each other, containing a stiffener connecting the adjacent said profile tubes; wherein each profile tube contains a ventilation hole located coaxially with said corresponding ventilation hole on the side surface of said collar portion; and contains on its side adjacent to the measured medium, a slot aligned axially with said corresponding ventilation hole on the side surface of said collar part; in this case, the housing for the electrodes contains electrodes rigidly fixed in each of the profile tubes, which are metal tubes with the same linear capacity, but differing in length, and the main electrode is made in length, mainly equal to the length of the housing for the electrodes, and each compensation electrode is made according to less than the length of the main electrode; moreover, the sensitive element of the sensor is connected to the base through the holes for the fasteners; moreover, the main electrode and each compensation electrode are connected to the electronic computing unit by means of metal rods connected to the insert sleeves, which are connected to the holes for the insert sleeves. 2. The system of claim. 1, characterized in that the base is made of metal or copolymer, or combinations thereof. 3. The system of claim. 1, characterized in that the connection of metal rods with embedded sleeves is carried out by means of a threaded connection. 4. The system of claim. 1, characterized in that the bushings are made of a dielectric material. 5. The system according to claim 4, characterized in that the connection of the embedded sleeves with the holes for the embedded sleeves is provided by means of a threaded connection. 6. The system according to claim 5, characterized in that the threaded connection of the holes for the insert sleeves and the insert sleeves contains a sealant. 7. System according to any one of paragraphs. 4-6, characterized in that the insert sleeves contain O-rings. 8. The system of claim. 1, characterized in that the hole in the niche for the output cable of the electronic computing unit contains a sealant. 9. The system of claim. 1, characterized in that the ventilation holes are additionally located asymmetrically in proximity to the base. 10. The system of claim. 1, characterized in that the main and each compensation electrodes are covered with an insulating shell. 11. System according to any one of paragraphs. 1-6, 8-10, characterized in that the main and each compensation electrodes are made of the same material as the metal rods. 12. The system according to claim. 1, characterized in that the sensitive element of the sensor is formed by connecting two geometrically similar sensitive elements of the sensor by means of a coupling. 13. The system according to claim. 12, characterized in that the connecting sleeve on each side of its body, adjacent to said slots on the body for the electrodes, contains coaxial slots made mainly along the entire length of the body of the connecting sleeve. 14. System according to any one of paragraphs. 1-6, 8-10, 12, 13, characterized in that the main and each compensation electrodes, metal rods, a housing for the electrodes and a connecting sleeve are made of the same material.

Images